A system for identifying an object impacting a vehicle bumper during a collision. The system receives acceleration values from each of a plurality of sensors and calculates a center strength value based on the acceleration values. The center strength value is indicative of the amount of force that is applied to the center of the vehicle bumper. The system then determines a preliminary impact location on the vehicle bumper based at least in part on the acceleration values. A normalized intrusion value is calculated based on the center strength value, the impact location, and a bumper stiffness factor. The bumper stiffness factor is indicative of the stiffness of the bumper at the impact location. The system then identifies the object impacting the vehicle bumper based at least in part on the normalized intrusion value.
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5. A method of identifying an object impacting a vehicle bumper during a collision, the method comprising:
receiving acceleration values from each of a plurality of sensors, the plurality of sensors including a left-side sensor positioned near a left side of the vehicle bumper, a right-side sensor positioned near a right side of the vehicle bumper, and a middle sensor positioned near a middle of a vehicle bumper;
calculating a center strength value of an impact based on the acceleration values, the center strength value being indicative of an amount of force that is applied to the middle location of the vehicle bumper,
determining an impact location on the vehicle bumper based at least in part on the acceleration values;
determining a bumper stiffness factor;
calculating a normalized intrusion value based on the center strength value, the impact location, and the bumper stiffness factor, and
identifying the object impacting the vehicle bumper based on the normalized intrusion value.
1. A system for identifying an object impacting a vehicle bumper during a collision, the system comprising:
a plurality of sensors including a left-side sensor positioned near a left side of the vehicle bumper, a right-side sensor positioned near a right side of the vehicle bumper, and a middle sensor positioned near the middle of the vehicle bumper;
a processor; and
a memory storing instructions that, when executed by the processor, cause the system to
receive acceleration values from each of the plurality of sensors,
calculate a center strength value of an impact based on the acceleration values, the center strength value being indicative of an amount of force that is applied to a middle location of the vehicle bumper,
determine an impact location on the vehicle bumper based at least in part on the acceleration values,
calculate a normalized intrusion value based on the center strength value, the impact location, and a bumper stiffness factor, the bumper stiffness factor being indicative of the stiffness of the bumper at the impact location, and
identify the object impacting the vehicle bumper based on the normalized intrusion value.
2. The system of
collecting calibration data including a plurality of acceleration values obtained by measuring the acceleration of the bumper caused by an impact at each of a plurality of locations on a surface of the vehicle bumper, wherein the impact at each of the plurality of locations is caused by an object of a defined mass traveling at a defined velocity,
defining an intrusion curve for the surface of the vehicle bumper by calculating the double integral of the plurality of acceleration values, and
determining a reciprocal of the intrusion curve.
3. The system of
calculating a first absolute sum of acceleration values received from the middle sensor during a period of time,
calculating a second absolute sum of acceleration values received from each of the left-side sensor, the middle sensor, and the right-side sensor during the period of time, and
calculating the center strength value by dividing the first absolute sum by the second absolute sum.
4. The system of
6. The method of
collecting calibration data including a plurality of acceleration values obtained by measuring the acceleration of the bumper caused by an impact at each of a plurality of locations on a surface of the vehicle bumper, wherein the impact at each of the plurality of locations is caused by an object of a defined mass traveling at a defined velocity,
defining an intrusion curve for the surface of the vehicle bumper by calculating the double integral of the plurality of acceleration values, and
determining a reciprocal of the intrusion curve.
7. The method of
calculating a first absolute sum of acceleration values received from the middle sensor during a period of time,
calculating a second absolute sum of acceleration values received from each of the left-side sensor, the middle sensor, and the right-side sensor during the period of time, and
calculating the center strength value by dividing the first absolute sum by the second absolute sum.
8. The method of
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This application is a continuation of U.S. patent application Ser. No. 12/891,373, filed on Sep. 27, 2010 and entitled “IMPACT SENSING AND IDENTIFICATION SYSTEM FOR PEDESTRIAN PROTECTION DEVICE,” the entire contents of which are incorporated by reference.
The present invention relates to systems for identifying an object contacting the front bumper of a vehicle during a collision. In many vehicle accidents involving a pedestrian, the pedestrian is struck by the front bumper of the vehicle. Serious injuries can occur if the pedestrian's head strikes the hood of the vehicle. Therefore, some vehicles are equipped with passive pedestrian protection systems such as pedestrian-friendly bumpers. Active pedestrian protection systems are also used. Some active pedestrian protection systems raise the hood of the vehicle to better absorb the force of the impact with a pedestrian when a pedestrian impact is detected.
In order to appropriately activate an active pedestrian protection system, the vehicle system must be able to accurately differentiate between a pedestrian and other objects that may impact the vehicle bumper during a collision. However, the stiffness of the bumper is not homogenous and the sensing area of a bumper is relatively wide. When an object strikes the vehicle bumper, the bumper deforms differently depending on the object's mass, the impact speed, and the bumper stiffness at the location of the impact. Assuming the same conditions of an object impact, i.e., same mass and speed, the bumper intrusion is different depending on impact location because the bumper stiffness is not homogeneous. As a consequence, it is possible to classify the object type by means of bumper intrusion, if bumper stiffness characteristics are known.
Some embodiments of the invention provide methods to determine the bumper stiffness at different locations on the bumper surface. These variations in stiffness are represented as a bumper stiffness curve. Using test data at different impact locations with the same object mass and speed, the intrusion at each impact location can be calculated by a double integral of the acceleration signal. Based on a simple spring-mass system model of the bumper, the bumper stiffness curve can be obtained by taking a reciprocal of the intrusion curve. The bumper stiffness curve is used for object classification.
In some embodiments, data from three accelerometers mounted in the bumper fascia is used. An object impact location is identified using two-dimensional data analysis based on a calculated offset and center strength. The offset distance from the bumper center can be calculated by comparing the difference of intrusions detected at left and right sensors. However, due to differences in stiffness across the surface of the bumper, it is hard to achieve a precise identification of impact location with only the offset value.
In one embodiment, the invention provides a system for identifying an object impacting a vehicle bumper during a collision. The system includes a plurality of sensors positioned to detect acceleration of the vehicle bumper relative to the vehicle. Changes in acceleration as detected by the sensors represent an intrusion into the bumper surface caused by an object colliding with the vehicle bumper. The plurality of sensors includes a left-side sensor, a right-side sensor, and a middle sensor. The system also includes a processor and a memory storing instructions. When the instructions are executed by the processor, the system receives acceleration values from each of the plurality of sensors and calculates a center strength value based on the absolute sum of the acceleration values. The center strength value is indicative of the amount of force that is detected at the middle location of the vehicle bumper. The system then determines a preliminary impact location on the vehicle bumper based at least in part on the acceleration values. A normalized intrusion value is calculated based on the center strength value, the impact location, and a bumper stiffness factor. The bumper stiffness factor is indicative of the stiffness of the bumper at the impact location. The system then identifies the object impacting the vehicle bumper based at least in part on the normalized intrusion value. In some embodiments of the invention, the system identifies the object as a pedestrian based at least in part on the normalized intrusion value and then activates the pedestrian protection system.
In some embodiments of the invention, the bumper stiffness factor is determined by collecting calibration data including a plurality of acceleration values obtained by measuring the acceleration of the bumper caused by an impact at each of a plurality of locations on the surface of the vehicle bumper. The impact at each of the plurality of locations is caused by an object of a defined mass traveling at a defined velocity. An intrusion curve is then defined for the surface of the bumper by calculating the double integral of the plurality of acceleration values. The bumper stiffness factor for each location of the bumper surface is then determined by taking the reciprocal of the intrusion curve.
In some embodiments of the invention, the system determines an impact location on the vehicle bumper by identifying a sensor of the plurality of sensors that detects the largest intrusion value. A freeze time is then determined as the time instant when a velocity of the intrusion detected by the sensor is equal or less than zero after being greater than zero for a period of time. The time instant is indicative of the moment when the vehicle bumper begins to rebound towards its original shape after being compressed by the impact. A normalized offset value is calculated by dividing the absolute value of the difference between an intrusion detected by the left-side sensor at the freeze time and an intrusion detected by the right-side sensor at the freeze time by the sum of the intrusions detected by the right-side sensor, the left-side sensor, and the middle sensor at the freeze time.
Other aspects of the invention will become apparent by consideration of the detailed description and accompanying drawings.
Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways.
As illustrated in
Because the bumper fascia will vibrate after impacting an object, the freeze time is defined as the time instant at which the data received from the acceleration sensors is evaluated to determine whether the vehicle has struck a pedestrian.
After the dominant sensor is identified and the freeze time has been determined, the system proceeds to determine the impact location or the distance of the impact from the center of the bumper. The offset calculation (step 325) is based on an intrusion value from each sensor at the freeze time. As described above, the intrusion value is obtained by determining the double integral of the acceleration signal from each of the three sensors 201, 203, and 205.
Force=(stiffness)×(intrusion)×(offset distance from center) (1)
The initial calculation of bumper offset assumes that the stiffness of the bumper is uniform at each location across the bumper fascia. Therefore, the rotational equilibrium of the impact as detected by each of the three sensors 201, 203, and 205 can be expressed by the following equation.
DsL×(d−c)=DsM×c+DsR×(d+c) (2)
Therefore, the normalized offset value of the impact from the center of the bumper can be obtained by the following equation.
However, the assumption that the stiffness of the bumper is uniform is not accurate. As such, the method illustrated in
The initial offset value and the center strength value are then subjected to a two-dimensional domain analysis in which each combination of center strength and initial offset value are projected onto a characteristics line having a −45° slope (step 335). Projecting the values onto such a characteristics line is appropriate because an impact with a small offset from center will have a high center strength value and an impact with a large offset from center will have a low center strength value.
As described above, the initial offset value calculated by step 325 is not accurate because it assumes that the stiffness of the bumper is uniform across the surface of the bumper. However, by projecting the data point onto characteristics line, the system calculates a new, more accurate projected offset based on the center strength of the impact. The projected offset value is the x variable of the projected point as illustrated in
A vehicle bumper structure consists of bumper beam, energy absorbing (EA) foam or plastic, and bumper fascia. When an object strikes the vehicle bumper, the bumper deforms depending on an object mass, an impact speed, and bumper stiffness at the location of the impact. Even though the object mass and impact speed remain the same regardless of the location of the impact, variations in bumper stiffness across the surface of the bumper affect the intrusion caused at the location of impact. In fact, the bumper stiffness is inversely proportional to the intrusion caused by an object. When the same impact forces are applied at different impact locations with the same object mass and velocity, each impact location will exhibit a different amount of intrusion depending on the bumper stiffness at the location of impact.
Therefore, to more accurately identify the object impacting the vehicle bumper, the system calculates a normalized intrusion value based on the calculated projected offset and a predetermined set of bumper stiffness values. A look-up table is used to identify a bumper stiffness factor (BuS factor) at the projected offset location (step 337). The normalized intrusion value is calculated by taking the sum of the intrusion values (DsSum) at the freeze time (step 339) and multiplying the sum (DsSum) by the bumper stiffness factor (BuS Factor) at the projected offset location (step 341).
In some systems, the look-up table used to identify the applicable bumper stiffness factor at each location of the bumper is generated based on calibration data. Under test conditions, a uniform force is exerted at a number of locations across the surface of the bumper. The force is exerted by an object of a defined mass at a defined velocity. The intrusions caused by the impact at each location are used to define an intrusion curve as illustrated in
The normalized intrusion value calculated according to
In other embodiments, the normalized intrusion value calculated according to
Thus, the invention provides, among other things, a system and method for determining a normalized intrusion value that is used to identify the type of object impacting a vehicle bumper regardless of the location of the impact. Various features and advantages of the invention are set forth in the following claims.
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